Laminar profile of visual response properties in ferret superior colliculus

Iain Stitt; Edgar Galindo-Leon; Florian Pieper; Gerhard Engler; Andreas K Engel

doi:10.1152/jn.00957.2012

Laminar profile of visual response properties in ferret superior colliculus

Standard

Laminar profile of visual response properties in ferret superior colliculus. / Stitt, Iain; Galindo-Leon, Edgar ; Pieper, Florian ; Engler, Gerhard ; Engel, Andreas K.

In: J NEUROPHYSIOL, Vol. 110, No. 6, 01.09.2013, p. 1333-45.

Research output: SCORING: Contribution to journal › SCORING: Journal article › Research › peer-review

Harvard

Stitt, I, Galindo-Leon, E , Pieper, F , Engler, G & Engel, AK 2013, 'Laminar profile of visual response properties in ferret superior colliculus', J NEUROPHYSIOL, vol. 110, no. 6, pp. 1333-45. https://doi.org/10.1152/jn.00957.2012

APA

Stitt, I., Galindo-Leon, E., Pieper, F., Engler, G., & Engel, A. K. (2013). Laminar profile of visual response properties in ferret superior colliculus. J NEUROPHYSIOL, 110(6), 1333-45. https://doi.org/10.1152/jn.00957.2012

Vancouver

Stitt I, Galindo-Leon E , Pieper F , Engler G , Engel AK. Laminar profile of visual response properties in ferret superior colliculus. J NEUROPHYSIOL. 2013 Sep 1;110(6):1333-45. https://doi.org/10.1152/jn.00957.2012

Bibtex

@article{3b1168262ac148949643e4057b63127b,

title = "Laminar profile of visual response properties in ferret superior colliculus",

abstract = "In the superior colliculus (SC), visual afferent inputs from various sources converge in a highly organized way such that all layers form topographically aligned representations of contralateral external space. Despite this anatomical organization, it remains unclear how the layer-specific termination of different visual input pathways is reflected in the nature of visual response properties and their distribution across layers. To uncover the physiological correlates underlying the laminar organization of the SC, we recorded multiunit and local field potential activity simultaneously from all layers with dual-shank multichannel linear probes. We found that the location of spatial receptive fields was strongly conserved across all visual responsive layers. There was a tendency for receptive field size to increase with depth in the SC, with superficial receptive fields significantly smaller than deep receptive fields. Additionally, superficial layers responded significantly faster than deeper layers to flash stimulation. In some recordings, flash-evoked responses were characterized by the presence of gamma oscillatory activity (40-60 Hz) in multiunit and field potential signals, which was strongest in retinorecipient layers. While SC neurons tended to respond only weakly to full-field drifting gratings, we observed very similar oscillatory responses to the offset of grating stimuli, suggesting gamma oscillations are produced following light offset. Oscillatory spiking activity was highly correlated between horizontally distributed neurons within these layers, with oscillations temporally locked to the stimulus. Together, visual response properties provide physiological evidence reflecting the laminar-specific termination of visual afferent pathways in the SC, most notably characterized by the oscillatory entrainment of superficial neurons.",

keywords = "Animals, Evoked Potentials, Visual, Female, Ferrets, Neurons, Reaction Time, Superior Colliculi, Visual Perception",

author = "Iain Stitt and Edgar Galindo-Leon and Florian Pieper and Gerhard Engler and Engel, {Andreas K}",

year = "2013",

month = sep,

day = "1",

doi = "10.1152/jn.00957.2012",

language = "English",

volume = "110",

pages = "1333--45",

journal = "J NEUROPHYSIOL",

issn = "0022-3077",

publisher = "American Physiological Society",

number = "6",

}

RIS

TY - JOUR

T1 - Laminar profile of visual response properties in ferret superior colliculus

AU - Stitt, Iain

AU - Galindo-Leon, Edgar

AU - Pieper, Florian

AU - Engler, Gerhard

AU - Engel, Andreas K

PY - 2013/9/1

Y1 - 2013/9/1

N2 - In the superior colliculus (SC), visual afferent inputs from various sources converge in a highly organized way such that all layers form topographically aligned representations of contralateral external space. Despite this anatomical organization, it remains unclear how the layer-specific termination of different visual input pathways is reflected in the nature of visual response properties and their distribution across layers. To uncover the physiological correlates underlying the laminar organization of the SC, we recorded multiunit and local field potential activity simultaneously from all layers with dual-shank multichannel linear probes. We found that the location of spatial receptive fields was strongly conserved across all visual responsive layers. There was a tendency for receptive field size to increase with depth in the SC, with superficial receptive fields significantly smaller than deep receptive fields. Additionally, superficial layers responded significantly faster than deeper layers to flash stimulation. In some recordings, flash-evoked responses were characterized by the presence of gamma oscillatory activity (40-60 Hz) in multiunit and field potential signals, which was strongest in retinorecipient layers. While SC neurons tended to respond only weakly to full-field drifting gratings, we observed very similar oscillatory responses to the offset of grating stimuli, suggesting gamma oscillations are produced following light offset. Oscillatory spiking activity was highly correlated between horizontally distributed neurons within these layers, with oscillations temporally locked to the stimulus. Together, visual response properties provide physiological evidence reflecting the laminar-specific termination of visual afferent pathways in the SC, most notably characterized by the oscillatory entrainment of superficial neurons.

AB - In the superior colliculus (SC), visual afferent inputs from various sources converge in a highly organized way such that all layers form topographically aligned representations of contralateral external space. Despite this anatomical organization, it remains unclear how the layer-specific termination of different visual input pathways is reflected in the nature of visual response properties and their distribution across layers. To uncover the physiological correlates underlying the laminar organization of the SC, we recorded multiunit and local field potential activity simultaneously from all layers with dual-shank multichannel linear probes. We found that the location of spatial receptive fields was strongly conserved across all visual responsive layers. There was a tendency for receptive field size to increase with depth in the SC, with superficial receptive fields significantly smaller than deep receptive fields. Additionally, superficial layers responded significantly faster than deeper layers to flash stimulation. In some recordings, flash-evoked responses were characterized by the presence of gamma oscillatory activity (40-60 Hz) in multiunit and field potential signals, which was strongest in retinorecipient layers. While SC neurons tended to respond only weakly to full-field drifting gratings, we observed very similar oscillatory responses to the offset of grating stimuli, suggesting gamma oscillations are produced following light offset. Oscillatory spiking activity was highly correlated between horizontally distributed neurons within these layers, with oscillations temporally locked to the stimulus. Together, visual response properties provide physiological evidence reflecting the laminar-specific termination of visual afferent pathways in the SC, most notably characterized by the oscillatory entrainment of superficial neurons.

KW - Animals

KW - Evoked Potentials, Visual

KW - Female

KW - Ferrets

KW - Neurons

KW - Reaction Time

KW - Superior Colliculi

KW - Visual Perception

U2 - 10.1152/jn.00957.2012

DO - 10.1152/jn.00957.2012

M3 - SCORING: Journal article

C2 - 23803328

VL - 110

SP - 1333

EP - 1345

JO - J NEUROPHYSIOL

JF - J NEUROPHYSIOL

SN - 0022-3077

IS - 6

ER -